Why we made this change

Visitors are allowed 3 free articles per month (without a subscription), and private browsing prevents us from counting how many stories you've read. We hope you understand, and consider subscribing for unlimited online access.

Finding Early Signs of Mad-Cow Disease

A comprehensive study of gene-expression changes could lead to new diagnostic tests.

Researchers have made a list of blood proteins that act as early indicators of a group of diseases including bovine spongiform encephalopathy (BSE), also known as mad-cow disease. Their results could lead to commercial early warning tests for the disease in farm animals. The methods used for the study–one of the most comprehensive analyses of the gene expression characteristic of a disease–are now being applied to other diseases and could lead to early diagnosis tests for other neurological diseases such as Alzheimer’s.

The human form of BSE, a fatal degenerative neurological disorder called Creutzfeldt-Jakob disease, can be contracted by eating meat contaminated with infectious agents called prions. Prions are proteins that cause other proteins to misfold, particularly in the brain and other neural tissue. In the first stages of the disease, prions replicate and accumulate in the brain. This is followed by abnormal activation of supportive cells, the degeneration of neural connections, and finally brain-cell death. By the time the disease can be diagnosed, these processes are already well under way.

In order to illuminate these ordinarily invisible processes, the researchers infected mice with prions and followed changes in the expression of every single gene in their brains at 10 points throughout the course of the disease. This global approach generated about 30 million data points. In order to separate signal from noise–that is, to find genes that were truly a significant part of the disease process–the researchers developed new statistical methods for looking at how the genes interact with one another in interrelated groups. Of an initialgroup of 7,400 implicated genes, they winnowed the number down to about 300 that are “at the heart of prion response,” says Leroy Hood, president and co-founder of the Institute for Systems Biology in Seattle, WA. Hood has pioneered this type of analysis, which he calls systems biology, over the past decade and led the new research with George Carlson, director of the McLaughlin Research Institute in Great Falls, MT.

The researchers further studied the 300 genes to find those that are known to code for proteins that are secreted into the blood. They discovered that some of those proteins could be found in the blood of infected mice 8 to 10 weeks before they started showing any symptoms. These results are described today in the journal Molecular Systems Biology. Hood says that the researchers are now looking into developing commercial tests for the human and bovine forms of prion disease, based on the blood biomarkers they have uncovered. Cows and humans have almost identical blood proteins to those uncovered in the mouse study.

“This global analysis let us pick up lots of features that were previously unknown,” says Hood. Only 200 of the implicated genes have a role in the disease process that is understood. So further study of the remaining 100 could lead to new insights into how prions cause disease. And all of the genes provide therapeutic targets for drug developers to investigate.

Hood now hopes to develop blood tests for other difficult-to-diagnose brain diseases. Having proven their analytical method in prion diseases, Hood says the group will apply it to mouse models of other degenerative diseases of the nervous system including Alzheimer’s and Huntington’s. Like Creutzfeldt-Jakob, “these diseases are difficult to diagnose in their early stages,” says Hood. The earlier the diagnosis, the better the outcomes are likely to be.

Become an MIT Technology Review Insider for in-depth analysis and unparalleled perspective.

Share

Tagged

Credit

I’m a freelance journalist based in San Francisco, California, and a contributing editor at MIT Technology Review, where I was previously on staff as materials science editor. I write about materials science, computing, and medicine. My favorite… More nanomaterial is carbon nanotubes and my favorite quasiparticle is the plasmon. I serve on the board of the Northern California chapter of the Society of Professional Journalists. I graduated from MIT’s science writing program in 2004.

You've read
of three
free articles this month.
Subscribe now for unlimited online access.
You've read
of three
free articles this month.
Subscribe now for unlimited online access.
This is your last free article this month.
Subscribe now for unlimited online access.
You've read all your free articles this month.
Subscribe now for unlimited online access.
You've read
of three
free articles this month.
Log in for more, or subscribe now for unlimited online access.
Log in for two more free articles, or subscribe now
for unlimited online access.